(2017) Daytime radiative cooling using near-black infrared emitters. (2016) Radiative cooling to deep sub-freezing temperatures through a 24-h day-night cycle. Proceedings of SSES Annual Congress, Neuchatel, Suisse.Ĭhen Z, Zhu L, Raman A, et al. (2013) Impacts of climate change on heating and cooling: a worldwide estimate from energy and macro-economic perspectives. Suichi T, Ishikawa A, Hayashi Y, et al (2018) Performance limit of daytime radiative cooling in warm humid environment. (2018) Self-adaptive radiative cooling based on phase change materials. J Quant Spectrosc Radiat Transfer 221: 155-163. (2018) Radiative cooling by tailoring surfaces with microstructures. J Quant Spectrosc Radiat Transfer 198: 179-186. (2017) Passive radiative cooling design with broadband optical thin-film filters. (2017) Double-layer nanoparticle-based coatings for efficient terrestrial radiative cooling. (2014) Passive radiative cooling below ambient air temperature under direct sunlight. Harrison AW, Walton MR (1978) Radiative cooling of TiO 2 white paint. doi: 10.2109/jcersj2.16164īerdahl P (1984) Radiative cooling with MgO and/or LiF layers. (2016) Fabrication of radiative cooling devices using Si 2N 2O nano-particles. doi: 10.1016/0165-1633(85)90001-2Įriksson TS, Jiang SJ, Granqvist CG (1985) Dielectric function of sputter-deposited silicon dioxide and silicon nitride films in the thermal infrared. doi: 10.3390/buildings8120168Įriksson TS, Jiang SJ, Granqvist CG (1985) Surface coatings for radiative cooling applications: silicon dioxide and silicon nitride made by reactive RF-sputtering. Santamouris M, Feng J (2018) Recent progress in daytime radiative cooling: is it the air conditioner of the future? Buildings 8: 168. doi: 10.3934/matersci.20įounda D, Santamouris M (2017) Synergies between urban heat island and heat waves in Athens (Greece), during an extremely hot summer (2012). Numerical techniques for electromagnetic simulation of daytime radiative cooling: A review.
The purpose of this paper is to provide strategies for selecting appropriate numerical techniques according to specific needs, evaluating, and analyzing the accuracy of the calculations, and explaining the cause of discrepancies between original and reference computations.Ĭitation: Jie Feng, Mattheos Santamouris. The accuracy analysis of these numerical techniques-including the source of errors in the original calculation, how accuracy of the result is evaluated, and explanations for the discrepancies in results between original and reference computations-are discussed in the final part, as well as the characteristics of numerical technique preferred in radiative cooling. After that, the application of these numerical techniques in daytime radiative cooling and the extent of the agreement between their results and those of a reference are discussed. Then the numerical techniques are reviewed and their advantages, limitations, and popularity in academic research are compared and analyzed.
In this paper, the commonly used software to solve Maxwell’s equations is first reported. The use of electromagnetic simulation in the design of such structures is essential to understand their optical properties and thus optimize the structures and materials selected before manufacture. Nanostructures developed in recent years have successfully achieved subambient feature during the daytime. Past research on radiative cooling failed to present subambient temperatures under direct sunlight due to the limited solar reflectance and emissivity in the atmospheric window. Radiative cooling is a well-researched cooling technique based on the ability of terrestrial surfaces to dissipate heat to the cold space.